CN102906557A - Microassembled imaging flow cytometer - Google Patents
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- G01N15/1468—Optical investigation techniques, e.g. flow cytometry with spatial resolution of the texture or inner structure of the particle
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Abstract
A microassembled imaging cytometer includes a sensing location that undergoes relative motion with a cell. Light from a light source is focused by a focusing element to a plurality of focused illumination spots or lines at the sensing location, illuminating the cell as the cell traverses the sensing location. A collection lens collects light emanating from the cell and refocuses the collected light onto an array light sensor. The focusing element may include an array of microlenses having spherical or aspheric surfaces. The system may include a processing unit that constructs a digital image of the cell based at least in part on signals produced by the array light sensor indicating the intensity and distribution of light falling on the array light sensor. The system may characterize cells using light emanating from the cells by fluorescence.
Description
The application be submitted on March 3rd, 2011, title for " Microassembled Imaging Flow Cytometer " the 13/039th, the PCT application of No. 990 U.S. Patent applications, and require to submit on March 15th, 2010, title for " Microassembled Confocal Imaging Flow Cytometer " the 61/314th, the right of priority of No. 056 U.S. Provisional Patent Application, whole disclosures of this U.S. Provisional Patent Application are incorporated herein by reference.
Background technology
Cytometry relates to the counting of biological cell and the technology specialty of sign.Fig. 1 shows the reduced graph of system that is called as the technology of imaging flow cytometry for execution.In the citation form of imaging flow cytometry, cell 101 is suspended in the fluid and at narrow transparent pipe 102 interior single files (single-file) and carries secretly.This is carried secretly and can realize by comprising in the several method that hydrodynamic force focuses on any.When each cell 101 during through the measuring position, light source 103 each cell 101 of irradiation.Light source 103 can for example be laser instrument.From the light of light source 103 because of 101 scatterings of just measured cell.Part light 105 is assembled by object lens 106 and is heavily led to form image at optical sensor 107 places.Optical sensor 107 can for example be the parts of microscope or camera head.Various opticses can cooperate with object lens 106 light 105 orientation sensors 107, for example comprise partially reflecting mirror 108 and supplementary lens 109.Output signal from sensor 107 is sent to processing unit 110, and these signals can be stored and analyze to this processing unit 110 with the identification information relevant with each cell, for example the size and some information relevant with the inner structure of cell of cell.
In some applications, can expect compact type thin born of the same parents metering system, for example for portable use or for the circulating tumor cell screening at Branch Clinic.
Summary of the invention
According to an aspect, a kind of little sense position, light source and concentrating element that comprises the relative motion of experience and cell as cell instrument that be assembled into.This concentrating element will be focused to from the light of light source a plurality of focusing points of irradiation at the sense position place, so that cell is shone by one or more focusing points of irradiation when passing sense position.This cell instrument also comprises array light sensor and collector lens (collection lens), and this collector lens will also focus on the array light sensor again from the light gathering that cell sends.In certain embodiments, little being assembled into as cell instrument also comprises runner (flow channel), and cell is carried by streaming flow by this runner, and this runner is at least in part by the wall gauge, and at least a portion of this wall is transparent basically.Relative motion can be produced by the mobile of cell at least in part.Relative motion can be at least in part produced by the mobile of the part of cell instrument.In certain embodiments, cell invests slide glass, and wherein, relative motion is produced by the mobile of slide glass at least in part.In certain embodiments, carry out irradiation to cell from a side of sense position, and carry out the sensing to the light that sends from cell from the same side of sense position.In certain embodiments, carry out irradiation to cell from a side of sense position, and carry out the sensing of the light that sends from cell from the not homonymy of sense position.Concentrating element can comprise the lenticular array with sphere.Concentrating element can comprise having aspheric lenticular array.Concentrating element can comprise at least one diffraction element.Light source can comprise laser instrument.In certain embodiments, array light sensor comprises the array of pixel and produces expression and drops on light intensity on the pixel and the signal of distribution, and this cell instrument also comprises the processing unit that makes up at least in part the digital picture of cell based on signal.In certain embodiments, processing unit is partly by to carrying out the digital picture that space correlation makes up cell at different time from the light intensity reading that the different piece of cell obtains.The speed of in certain embodiments, passing sense position based on cell is at least in part carried out the association to the light intensity reading of obtaining from the different piece of cell at different time.Concentrating element can comprise lenticular linear array.Concentrating element can comprise lenticular two-dimensional array.Array light sensor can comprise the linear array of pixel.Array light sensor can comprise the two-dimensional array of pixel.In certain embodiments, little being assembled into as cell instrument also is included at least one optical filter between sense position and the array light sensor.In certain embodiments, array light sensor comprises at least one sensor that is selected from following group: this group comprises charge coupling device sensor, electron multiplication charge coupling device sensor, avalanche photodide sensor, photomultiplier and complementary metal oxide semiconductor (CMOS) sensor.In certain embodiments, a plurality of focusing points of irradiation form the array that focuses on points of irradiation, and this array is with respect to the motion of cell and sense position and crooked.Little being assembled into as cell instrument can also comprise optical element near array light sensor, this optical element with little be assembled into be configured to as cell instrument basically confocal.Optical element can comprise the array of micropore (microaperture).Optical element can comprise fibre bundle.In certain embodiments, the collector lens gathering also focuses on the light that sends by fluorescence from cell again.
According on the other hand, a kind of method of carrying out cytometry comprises: produce light beam with light source; To be focused to from the light of light beam at a plurality of focusing points of irradiation of experience with the sense position place of the relative motion of cell; And will also again focus on the array light sensor from the light gathering that cell sends.The method also comprises: produce expression from array light sensor and drop on light intensity on the array light sensor and the signal of distribution; And come at least in part based on the digital picture that makes up cell from the signal of array light sensor with processing unit.The method can also comprise: signal is converted to the numerical value that expression drops on the pattern of the light on the array light sensor.In certain embodiments, the digital picture of structure cell also comprises: a series of sequential readings of obtaining the light that drops on the array light sensor; Focus on point of irradiation corresponding to each and follow the tracks of individually photoreading from array light sensor; And come independent photoreading is carried out spatial calibration based on the gait of march of known system geometries, cell and the frequency that obtains photoreading at least in part.In certain embodiments, the method also comprises: the light that sends from cell is carried out filtering, optionally to stop by the light of the wavelength of light source emission and the light of the wavelength that sends by fluorescence from cell is passed through.In certain embodiments, the method also comprises: the optical element near array light sensor is set, this optical element with little be assembled into be configured to as cell instrument basically confocal.
According on the other hand, little sense position, light source and concentrating element that comprises experience and the relative motion of cell as cell instrument that be assembled into.This concentrating element will be focused to from the light of light source many focusing illuminated line at the sense position place, so that cell is focused on the illuminated line irradiation by one or more when passing sense position.Little being assembled into as cell instrument also comprises optical sensor and collector lens, and this collector lens will also focus on the array light sensor again from the light gathering that cell sends.This optical sensor can comprise the array of pixel.
According on the other hand, little sense position, light source and concentrating element that comprises experience and the relative motion of cell as cell instrument that be assembled into.This concentrating element will be focused to from the light of light source a plurality of focusing points of irradiation or the line at the sense position place, so that cell is shone by one or more focusing points of irradiation or line when passing sense position.Little being assembled into as cell instrument also comprises: array light sensor; Collector lens will assemble from the light that cell sends also again focusing on the array light sensor; Processing unit is analyzed signal from optical sensor so that cell is sorted out; And sorting mechanism, the cell of sorting out is guided at least two collection channels one.
Description of drawings
Fig. 1 shows the reduced graph for the system that carries out the imaging flow cytometry.
Fig. 2 shows little according to an embodiment of the invention signal oblique view that is assembled into the picture cell instrument.
Fig. 3 shows according to an embodiment of the invention, little orthogonal view that is assembled into the part of picture cell instrument of Fig. 2.
Fig. 4 shows according to an embodiment of the invention, the little top schematic view that is assembled into the part of picture cell instrument example of the example of Fig. 2.
How Fig. 5 A shows according to an embodiment of the invention, be assembled into the photoreading that obtains as the different sensor site place of cell instrument Fig. 2 little changes according to the time.
Fig. 5 B shows the track of Fig. 5 A after spatial calibration.
Fig. 6 shows the digital picture according to the data construct of Fig. 5 A and Fig. 5 B.
Fig. 7 shows little according to an embodiment of the invention assembling confocal imaging cell instrument.
Fig. 8 shows the little assembling confocal imaging cell instrument according to other embodiment.
Fig. 9 shows the little picture cell instrument that is assembled into according to other other embodiment.
Figure 10 shows little crooked effect that is assembled into some parts in the picture cell instrument of Fig. 9.
Figure 11 shows the little picture cell instrument that is assembled into according to other embodiment, wherein shines and the sensing cell from the same side of sense position.
Figure 12 shows the little assembling confocal imaging flow cytometer according to other embodiment.
Figure 13 shows according to an embodiment of the invention, the orthogonal view of the system of Figure 12.
Figure 14 shows and can pass a series of light intensity readings that the sensing region of the system of Figure 12 produces by a cell.
The determination and analysis system that Figure 15 shows according to an embodiment of the invention, couple with sorting mechanism.
Embodiment
Fig. 2 shows little according to an embodiment of the invention signal oblique view that is assembled into picture cell instrument 200.Fig. 2 not necessarily draws in proportion, and for clear, can omit or simplify some parts.
For purpose of the present disclosure, term " little assembling " means with assembling such as lower member, equipment and technology: these parts, equipment and technology make it possible to build-up tolerance (assembly tolerance) is assembled than the much smaller very little structure of build-up tolerance that can utilize traditional machine tool and mounting technology to realize.For example, each parts can have functional character or about 5 to 100 microns size, and can be that the equipment of about 0.1 to 10 micron widget is assembled together these parts with become the operation build-up tolerance by specialized designs.Little mounting technology can shorten in addition relatively far apart optics or the spacing of mechanical part, thereby make it possible to realize integrated and parallel.
The imaging cell instrument 200 of little assembling comprises runner (flow channel) 201, and cell is transferred in the fluid that flows by this runner.Runner 201 is by wall 202 gauges, and at least a portion of this wall 202 is transparent basically.This system also comprises light source 203, and this light source 203 produces the light beam 204 that is used for irradiating cell 101.Light beam 204 is preferably coherent light beam, and therefore, light source 203 is laser instrument expediently.
Concentrating element 205 receives from the light of light source 203 and light is focused to a plurality of focusing points of irradiation 206 at sense position 207 places in runner 201.Because cell 101 flows through runner 201, sense position 207 and cell 101 experience relative motions.A time in office, cell 101 can be by one or more point of irradiation 206 irradiations when passing sense position 207.In example system 200, concentrating element 205 comprises the two-dimensional array of lenticule 205A, but can use the concentrating element of other kinds.For example, concentrating element 205 can be transmission or reflection hologram or the another kind of concentrating element of Fresnel zone plate array, original nanohole array.Each lenticule 205A can produce point of irradiation 206(for clear, and two points of irradiation 206 only are shown in Fig. 2.) sense position 207 can be smooth basically, and limited by the track that focuses on point of irradiation 206.
When cell 101 ran into a focusing point of irradiation, light 208 sent from cell 101.For example, cell 101 can be marked with the fluorophore that sends light when being encouraged by the focused light from light beam 204 by fluorescence.As an alternative, little being assembled into can be with the direct imaging of carrying out cell 101 from the light of cell 101 scatterings as cell instrument 200.At least a portion from the light 208 that cell 101 sends is assembled by collector lens 209 and is again focused on the array light sensor 210.(other light beams 214 in Fig. 2, have been shown in broken lines, the light that these other light beams 214 expressions can be sent from cell 101 when cell 101 is in diverse location in the runner 201.) can be placed between sense position 207 and the array light sensor 210 such as one or more wave filters of wave filter 211.For example, wave filter 211 may reside between runner 201 and the lens 209, between lens 209 and the array light sensor 210 or between the element of lens 209 (in the situation that lens 209 comprise a plurality of elements).For example, wave filter 211 can optionally stop the light by the wavelength of light source 203 emission, and the light of the wavelength that sends by fluorescence from cell 101 is passed through, and basically all produces by fluorescence so that arrive the light of array light sensor 210.For example, array light sensor 210 can be the parts of digital camera device, and can comprise the oldered array of light activated element, and wherein light activated element can be called pixel.Array light sensor 210 may produce under the control of unshowned other electronic equipments and be illustrated in the signal that drops on the light intensity on each pixel in the given time shutter.Thereby these signal indications are in the light intensity and the distribution that drop between exposure period on the array light sensor 210.These signals can be transmitted 212 to processing unit 213 to store, to analyze or to show.Can for example with the analog to digital converter (not shown) signal be converted to digital value, this analog to digital converter may reside in any convenient location in the system.Processing unit 213 can comprise microprocessor and other electronic units, and can be for example for being specifically programmed as to carry out the multi-purpose computer of various analyses from the signal of array light sensor 210.As being described in more detail after a while, processing unit 213 can be collected by the obtained a series of digital pictures from array light sensor 210 in time interval, and can make up according to this image series the image of cell 101.
Fig. 3 shows such as little orthogonal view that is assembled into the part of picture cell instrument 200 that see along the Y-direction shown in Fig. 2, exemplary.Lenticule 205A receiving beam 204.Lenticule 205A can have sphere (that is, the curved surface of each lens can be the part of sphere), and perhaps in order to obtain very little some size and high resolving power, lenticule 205A can preferably have aspheric surface.Become known for constructing the technology of the lenticular array that comprises aspherical microlens.For example referring to Hongmin Kim, Gibong Jeong, Young-Joo Kim, and Shinill Kang, " Design and Fabrication of Aspheric Microlens Array for Optical Read-Only-Memory Card System ", Japanese Journal of Applied Physics, Vol.45, No.8B, 2006, pp.6708-6712, its whole disclosures are incorporated herein by reference.The size of lenticule 205A and spacing can be any spendable value, but preferably, the center of lenticule 205A can be separated by between 5 to 20 microns.In one exemplary embodiment, each lenticule 205A can have about 15 microns diameter, and lenticule 205A can be separated by about 15 microns and be compressed thick and fast.Preferably, make any gap between the lenticule 205A all light tight, so that pass through the focus surface of a lenticule 205A by any light of concentrating element 205.207 distance can for example be about 10 to 100 microns from concentrating element 205 to sense position, and preferably less than 50 microns.According to the expectation picture element density of final resulting image, implement system of the present invention and can comprise the lenticule more more or less than shown lenticule.In certain embodiments, can use about 200 lenticules.
The part of each lenticule 205 focused beam 204 is so that produce a plurality of focusing points of irradiation 206 at the sense position place.Sense position 207 is preferably near the center of runner 201, and when cell 101 passed runner 201, runner 201 preferably was constrained to cell 101 and surrounds sense position 207.Although system 200 can be suitable for characterizing various cells and with any suitable speed operation, typical cells 101 can be about 10 to 20 microns wide, and can pass runner 201 with the speed of 1 to 50 millimeter of per second for example.The sampling resolution of system is determined by the speed that obtains digital picture and the speed that cell 101 passes runner 201.The optical resolution of this system is mainly set according to the size that focuses on point of irradiation 206.Aspherical microlens 205A can realize that size is 0.5 micron or less focus.
The light 208 that sends from cell 101 is assembled by collector lens 209 and is again focused on the array light sensor 210.Although in Fig. 3, collector lens 209 is depicted as simple biconvex lens, can use any suitable lens configuration, comprise the lens of plano-convex lens, concave-convex lens, multielement lens or other kinds.Because the optical resolution of system is mainly set according to the size that focuses on point of irradiation 206, therefore, the performance of collector lens 209 can not be crucial, as long as be directed to the lip-deep discrete and recognizable pond of array light sensor 210 from the light of various lenticule 205A.Processing unit 213 can be only to the intensity of the light 208 of suing for peace from the reading of several neighbors of sensor 210 to estimate to send from any specific focusing point of irradiation 206.In system shown in Figure 3, collector lens 209 is arranged to and carries out the unit amplification, but this is not requirement.Larger or the less image that collector lens 209 can be configured to focus on point of irradiation 206 projects on the array light sensor 210.In certain embodiments, collector lens 209 can throw to compare with the unit enlarged image and amplify the image of 2X to 5X.210 distance can be any suitable distance from runner 201 to array light sensor, but can be for example about 5 millimeters to 15 millimeters.
Also can use in an embodiment of the present invention the array light sensor of other kinds, be developed especially recently the sensor for the quick application of height.For example, array light sensor 210 can comprise the array of complementary metal oxide semiconductor (CMOS) (CMOS) sensor, electron multiplication charge-coupled image sensor (EMCCD) sensor, avalanche photo diode (APD) sensor, photomultiplier (PMT) or APD or PMT.Also can use a plurality of sensors.For example, each lenticule 205A can use a discrete sensor.
If there is wave filter 211, wave filter 211 dichroic filter for forming by optionally applying transparent substrates for example then, so that only the light of specific one or more wavelength bands is easily by wave filter 211, and the light of other wavelength basically filtered device 211 stop.Measuring the light time of sending by fluorescence from cell 101 with cytolytic dose system 200, wave filter 211 is particularly useful.Wave filter 211 can be configured to basically stop the light of the wavelength that comprises in the light beam 204, and the light that makes fluorophore in the cell 101 send the wavelength band of fluorescence passes through basically.
Because the spacing of lenticule 205A can be compared with the size of cell 101, so concentrating element 205 can be with respect to the motion between cell 101 and the sense position 207 and crooked, to guarantee that cell 101 is focused point of irradiation 206 and covers well through sense position 207 time.
Fig. 4 shows the top schematic view on Z direction surface that see, array light sensor 210 as shown in Figure 2, wherein cell 101 and to focus on point of irradiation 206 overlapping so that the effect that makes the array that focuses on point of irradiation 206 crooked with respect to runner 201 to be shown.Such as what can see in the example of Fig. 4, even focus on point of irradiation 206 relative to each other interval relatively wide (corresponding to the spacing of lenticule 205A), cell 101 also will run into nine different focusing points of irradiation when passing runner 201.Name a person for a particular job for these nine and describe to cross over the nearer path A-I in interval of cell 101, so that cell 101 is covered during it passes well.
In order to make up the digital picture of cell 101, system 200 obtains a series of sequential readings of the light that drops on the array light sensor 210.Focusing on position corresponding to point of irradiation 206 with each on the array light sensor 210 is identified and is followed the tracks of individually.Fig. 5 A shows when cell 101 passes runner 201 in the photoreading at the sensing station place corresponding with path A-I and can how change according to the time.As can be seen, cell 101 at first meets with irradiation along path G, and little by little meets with irradiation at follow-up time along other paths, and wherein, path F is for receiving the final path of light.Because the gait of march of known system geometry and cell 101, and the known frequency that takes the reading therefore can be by spatial calibration to form the digital picture of cell 101 along the obtained light intensity track of path A-G.The spatial calibration track has been shown among Fig. 5 B.Then, the spatial calibration data can be combined into the digital picture of cell 101, as shown in Figure 6, wherein, higher light intensity illustrates with more shallow gray shade than lower light intensity.Certainly, the focusing point of irradiation 206 of varying number can be used according to the cell instrument of other embodiment, and the resolution image higher than resolution shown in Figure 6 can be produced.
In this example, the ad-hoc location from cell 101 produces the higher light intensities signal by the more light that fluorescence sends, thereby the part with more fluorophore of cell is illustrated as more shallow in Fig. 6.If expectation, this relation can be reversed, so that the part of sending more light of cell 101 is illustrated as in final resulting digital picture is darker.If the optical wavelength direct imaging (not utilizing fluorescence) that system 200 is used for to be included in light beam 204, cell 101 can be considered to shade is projected on the array light sensor 210 so, thereby the comparatively dense of cell 101 part can produce the less light that arrives array light sensor 210.
In certain embodiments, little being assembled into as cell instrument can be included near the array light sensor 210 optical element, this optical element with system configuration for basically confocal.Fig. 7 shows little according to an embodiment of the invention assembling confocal imaging flow cytometer 700.Several parts of system 700 are similar to several parts of system 200 discussed above, and are endowed the Reference numeral identical with these several parts in the system 200.By add fibre bundle 701 near array light sensor 210, system 700 is configured to basically confocal.Preferably, except the narrow that allows light to enter, the top 702 of each optical fiber in the fibre bundle 701 is configured to light tight or reflective.For example, the part in the optical fiber can be coated with aluminium or gold, and it has been plated 100 nanometers to 200 nanometer thickness.Then, optical fiber with the photoconduction that allows to enter to array light sensor 210.Therefore, work in the mode that is similar to orifice plate in the end 702 of optical fiber, and the light that sends from sense position 207 with preferential permission enters and preferentially stops the light that sends from other axial locations to enter.For example, send and the light of scioptics 209 imagings is followed light shafts such as pencil 706 from the point of irradiation 206 in sense position 207, and when it arrives the end face of an optical fiber 701 by tight focus, thereby allow to enter by optical fiber.The light that sends from the position below sense position 207 can be dispersed according to the pencil that is similar to pencil 703, to be converged to for example pencil of pencil 705 by lens 209.Pencil 705 is not converged to tight point when it arrives optical fiber 701, therefore, stoped major part to enter by the lightproof part of optical fiber end.Similarly, the light that sends above sense position 207 will be assembled when it arrives optical fiber 207 and again disperse, and therefore, is also stoped major part to enter by optical fiber 701.Therefore, system 700 preferentially make the light that sends from sense position 207 by and preferentially stop some light that send from other axial locations.
Fig. 8 shows little assembling confocal imaging flow cytometer 800 according to other embodiments of the invention.Several parts of system 800 are similar to several parts of system 200 discussed above, and are endowed the Reference numeral identical with these several parts in the system 200.In addition, another optics is the near surface that orifice plate 801 is arranged on array light sensor 210.Except the array in hole 802, orifice plate 801 is basically light tight.Each hole 802 is corresponding to a lenticule 205A, and is calibrated to allow the light from the focusing point of irradiation 206 of correspondence sends to pass through.Optical element 801 is configured to system 800 basically confocal.That is to say, hole 802 has and stops from the light of axial location rather than the effect of light in the sense position.For example, light shafts 803 send from the position below sense position 207 804 just in time.Final resulting light is focused into another light shafts 805 again by collector lens 209, and these light shafts 805 are more slowly assembled than the pencil 806 that is derived from sense position 207.Therefore, light shafts 805 are partly stopped by a hole 802, are represented by shadow region 807.Since system 800 preferentially make the light that sends from sense position 207 by and preferentially stop some light that send from other axial locations, so this system can be than the image that is not configured to basically confocal system and produces high-contrast more or resolution.Ideally, orifice plate 801 is placed on the focal position place of lens 209, so that the light that hole 802 can very little and effectively be distinguished the light that sends from sense position 207 and send from axial location rather than sense position 207.So, be derived from each beam that focuses on point of irradiation 206 and when it arrives array light sensor 210, can slightly disperse, and processing unit can be by to suing for peace to estimate the intensity of each light shafts from the reading of several pixels of array light sensor 210.
Fig. 9 shows the little assembling confocal imaging flow cytometer 900 according to other embodiment.In this embodiment, substitute lenticular two-dimensional array, used the linear array 901 of lenticule 205A.Preferably, microlens array 901 is crooked with respect to runner 201.Correspondingly, linear array optical sensor 902 is set up, and also preferably crooked with respect to runner 201, and calibrates with microlens array 901.Linear array optical sensor 902 can comprise the sensor of any suitable kind, comprises ccd sensor, EMCCD sensor, APD, PMT, cmos sensor or another kind of sensor.Although it is can the interval relatively wide that the focusing point of irradiation 206 that provided by microlens array 901 is provided Figure 10, crooked layout has guaranteed that the cell 101 that passes runner 201 will be covered and relatively thick and fast imaging well during it passes.The structure of the digital picture of 900 pairs of cells 101 of system and above similar with reference to the described structure of Fig. 4-6.System 900 can also comprise system 900 is configured to basically confocal one or more optical elements, and the light that can sensing sends by fluorescence from cell 101, perhaps can carry out direct imaging.
Figure 11 shows the little assembling confocal imaging flow cytometer 1100 according to other embodiment.Although said system 200 is from opposite side irradiation and the sensing cell of sense position 207, little picture cell instrument 1100 that is assembled into is from the same side irradiation and the sensing cell of sense position 207.In system 1100, light beam 204 is focused element 205 and is focused to a plurality of focusing points of irradiation 206.Concentrating element 205 is shown as the array of lens, but can be any suitable concentrating element.Wavelength selects catoptron 1101 with light again pilot flow 201, so that focus on point of irradiation at sense position 207 places.For example, catoptron 1101 can incide the dichronic mirror that all light on it reflect basically for being configured to make from light beam 204.Light 208 sends from cell 101, and at least a portion in the light 208 that sends is assembled by collector lens 209 and again focused on.System 1100 can be particularly suitable for using the light that sends by fluorescence to make cell imaging, and this is because wavelength selects catoptron 1101 can be configured to make cell 101 basically to pass through by all light in the wavelength band of fluorescence emission.Optional additional filter 211 can further be regulated the gathered light 208 that focuses on the array light sensor 210.Array light sensor 210 can be two-dimensional array or linear array, and can comprise the optical sensor of any suitable kind, comprises ccd sensor, EMCCD sensor, APD, PMT, cmos sensor or another kind of sensor.System 1100 can comprise that with system configuration be basically confocal optical element, for example has orifice plate 801 or the fibre bundle in hole 802.Make up the digital picture of cell 101 with system 1100 to carry out about system's 200 descriptions and in the similar mode of mode shown in Fig. 4-6 with above.
Figure 12 shows the little assembling confocal imaging flow cytometer 1200 according to other embodiment.Several parts of system 1200 are similar to the several parts in the said system 200, and are endowed the Reference numeral identical with these several parts in the system 200.Cell such as cell 101 passes by the runner 201 of wall 200 gauges.Light source 203 produces light beam 204.Light source 203 can for example be laser instrument.Concentrating element 1201 receives from the light of light source 203 and this light is focused on.Compare with the concentrating element 205 of system 200, concentrating element 1201 for will be focused to from the light of light beam 204 many lines (such as, sense position 207 places or near the illuminated line 1202 of irradiating cell) array or the another kind of optics of cylindrical lens 1201A.The light that sends by scattering or fluorescence from cell is assembled by collector lens 209 and is again focused on orifice plate 1203.Orifice plate 1203 comprises a series of narrow slots 1204 that are calibrated to receive from the focused light of illuminated line 1202.Therefore, this system is confocal, and this is because this system is tending towards suppressing the light that sends from away from the Z axis position of sense position 207.Light by orifice plate 1203 arrives optical sensor 210.(for clear, from Figure 12, omitted optional wave filter.) optical sensor 210 produces the signal that expression drops on the light intensity on the sensor, and these signals can be transmitted 212 to processing unit 213 to store, to analyze or to show.
Produce mutually enough near illuminated line 1201 so that several lines can drop on the individual cells simultaneously although show system 1200, this is not requirement, in fact, and the concentrating element 1201 generation intervals illuminated line larger than the expectation size of cell preferably.Because each interval is wider usually in runner 201 for cell, has the wider illuminated line in interval 1202 and can cause once only producing light from an illuminated line and a cell that arrives sensor 210 any.In this arrangement, sensor 210 can be simplified, and even can be for measured light intensity but do not comprise the sensor of simple photodiode, photomultiplier or other kinds of pel array.
Figure 13 shows the according to an embodiment of the invention orthogonal view of system 1200.As can be seen, slit 1204 is confocal with system configuration, for example, stops the part 1301 of the light shafts 1302 that come from the position of departing from sense position 207 to enter.
Figure 13 also shows according to an embodiment of the invention system 1200 on the other hand.Runner 201 tilts with respect to sense position 207.In Figure 13, this inclination illustrates with angle θ, and in order to clearly demonstrate, this angle θ compares with practical application and may be exaggerated.Runner 201 is combined with the confocal aspect of system 1200 with respect to the inclination of sense position 207 and is produced each rectangle pond as an example of pond 1303 example, that drop on the light on the sensor 210, and it is derived from the Z axis position unique with respect to cell 101 basically.
Figure 14 shows and can pass the sensing region 207 of system 1200 and a series of light intensity readings of producing by a cell 101.These readings are obtained chronologically, so each reading all is illustrated in the light intensity that special time sends from cell 101, it is corresponding to the specific X-axis position of cell 101, and also corresponding intracellular specific X-axis position.For example, can enough take the reading continually so that cell 101 is advanced 0.25 to 0.5 micron between reading.Because runner 201 tilts, so each reading is also corresponding to intracellular specific Z axis position.Figure 14 can represent the measurement result of the light that sends by fluorescence from cell 101, and this is because in the time between illuminated line, recorded low-down illumination levels at cell 101.In the hypothetical examples of Figure 14, when passing an illuminated line 1201, the nucleus of cell 101 obtains the maximum intensity reading.Even sensor 210 is the single-sensors that do not have pixel, the reading that makes up also can provide the information relevant with the structure of cell 101, at least on the X-Z xsect.If sensor 210 comprises the array of each pixel really, so also can obtain some structural informations relevant with the Y-direction structure of cell.In some imaging applications of using the multicolor fluorescence imaging, expectation provides independent detecting device for every kind of iridescent.
Although in system 1200, only show six cylindrical lens 1201A, it will be understood by those skilled in the art that and to use other quantity.For example, can produce nearly 20 to 100 illuminated line.In one exemplary embodiment, can use about 40 cylindrical lenses, each cylindrical lens all has about 25 microns radius (50 microns width), thereby sensing region 207 is about 2 millimeters long at directions X.If runner 201 has about 50 microns height, runner 201 is about θ=50/2000=0.025 radian with respect to the preferred angled of sense position 207 so.According to height and employed lenticular quantity and the size of runner, other suitable pitch angle are possible.
It will be understood by those skilled in the art that and can also be constructed as follows system: this system comes in sense position 207 places formation illuminated line with the concentrating element that is similar to concentrating element 1201, and from the same side irradiation and sensing cell, this is similar with the mode that realizes irradiation and sensing in system shown in Figure 9 900.
According to other embodiments of the invention, can come cell is carried out sorting with the result of the analysis of being carried out by processing unit 213.For example, processing unit 213 can be analyzed the signals that produced by sensor 210 or 902 to determine that whether specific cells is as circulating tumor cell.Circulating tumor cell can characterize by the concrete measurement result of cell size, nucleus size and nucleocytoplasmic ratio, and using according to an embodiment of the invention, system can detect above whole.The specific cells that satisfies the particular detection standard with isolation can be combined with sorting mechanism in the determination and analysis system.Such system has been shown among Figure 15, and use system 1200 is as the example detection device.Based on the analysis to specific cells, processing unit 213 can be sorted out and signal is sent 1501 to separation unit 1502 cell, two passages 1503 that this separation unit 1502 is used for each cell guiding to collect, one of 1504.For example, separation unit 1502 can comprise for the piezoelectricity that is heavily led in the path of each cell or optical force element.
Although embodiments of the invention have been illustrated as scanning the cell that is limited in the linear tube, but it will be understood by those skilled in the art that, embodiments of the invention can be used in any the system that uses in the various cell Transfer Technologies, and wherein the cell Transfer Technology comprises electrophoresis, pressure driven flow, light tweezer, motorized precision translation stage etc.Cell can be used as useful load and transports transmission with oil emu, the wetting actuating drop of electricity consumption or by the magnetic that utilizes marked by magnetic bead to assist.The Mechanical Moving of slide glass that can be by the carrying cell, the parts by cell instrument when cell keeps static movement or by at cell and cell instrument parts with friction speed or the relative motion when moving in different directions, the relative motion between cell and the sense position is provided.Claim is not limited by employed cell transmission method.
In claims, term " (a or an) " refers to " one or more ".When the narration introduced step or element, term " comprises (comprise) " and distortion (such as, " comprising (comprise and comprising) ") refer to add other step or element is optionally and not to be left out.For the purpose that is aware and understand, described now the present invention in detail.But, one skilled in the art will understand that and can carry out within the scope of the appended claims certain variation and modification.
Claims (33)
1. little being assembled into looks like cell instrument, comprising:
Sense position, the relative motion of experience and cell;
Light source;
Concentrating element, described concentrating element will be focused to from the light of described light source a plurality of focusing points of irradiation at described sense position place, so that described cell is shone by one or more described focusing points of irradiation when passing described sense position;
Array light sensor; And
Collector lens will assemble also from the light that described cell sends again focusing on the described array light sensor.
2. little picture cell instrument that is assembled into according to claim 1 also comprises runner, and described cell is carried by streaming flow by described runner, and described runner is at least in part by the wall gauge, and at least a portion of described wall is transparent basically.
3. little being assembled into according to claim 1 looks like cell instrument, and wherein, described relative motion is produced by the mobile of described cell at least in part.
4. little being assembled into according to claim 1 looks like cell instrument, and wherein, described relative motion is produced by the mobile of a part of described cell instrument at least in part.
5. little being assembled into according to claim 1 looks like cell instrument, and wherein, described cell invests slide glass, and described relative motion is produced by the mobile of described slide glass at least in part.
6. little picture cell instrument that is assembled into according to claim 1 wherein, is carried out irradiation to described cell from a side of described sense position, and is carried out the sensing to the light that sends from described cell from the same side of described sense position.
7. little picture cell instrument that is assembled into according to claim 1 wherein, is carried out irradiation to described cell from a side of described sense position, and carries out sensing to the light that sends from described cell from the not homonymy of described sense position.
8. little being assembled into according to claim 1 looks like cell instrument, and wherein, described concentrating element comprises the lenticular array with sphere.
9. little being assembled into according to claim 1 looks like cell instrument, and wherein, described concentrating element comprises having aspheric lenticular array.
10. little being assembled into according to claim 1 looks like cell instrument, and wherein, described concentrating element comprises at least one diffraction element.
11. little picture cell instrument that is assembled into according to claim 1, wherein, described light source comprises laser instrument.
12. little picture cell instrument that is assembled into according to claim 1, wherein, described array light sensor comprises the array of pixel and produces expression and drop on light intensity on the described pixel and the signal of distribution, and described cell instrument also comprises the processing unit that makes up at least in part the digital picture of described cell based on described signal.
13. little picture cell instrument that is assembled into according to claim 12, wherein, described processing unit is partly by to carrying out the digital picture that space correlation makes up described cell at different time from the light intensity reading that the different piece of described cell obtains.
14. little picture cell instrument that is assembled into according to claim 13, wherein, the speed of passing described sense position based on described cell is at least in part carried out the association to the light intensity reading of obtaining from the different piece of described cell at different time.
15. little picture cell instrument that is assembled into according to claim 1, wherein, described concentrating element comprises lenticular linear array.
16. little picture cell instrument that is assembled into according to claim 1, wherein, described concentrating element comprises lenticular two-dimensional array.
17. little picture cell instrument that is assembled into according to claim 1, wherein, described array light sensor comprises the linear array of pixel.
18. little picture cell instrument that is assembled into according to claim 1, wherein, described array light sensor comprises the two-dimensional array of pixel.
19. little picture cell instrument that is assembled into according to claim 1 also is included at least one optical filter between described sense position and the described array light sensor.
20. little picture cell instrument that is assembled into according to claim 1, wherein, described array light sensor comprises at least one sensor that is selected from following group: this group comprises charge coupling device sensor, electron multiplication charge coupling device sensor, avalanche photodide sensor, photomultiplier and complementary metal oxide semiconductor (CMOS) sensor.
21. little picture cell instrument that is assembled into according to claim 1, wherein, described a plurality of focusing points of irradiation form the array that focuses on points of irradiation, and described array is with respect to the motion of described cell and described sense position and crooked.
22. according to claim 1 little be assembled into the picture cell instrument, also comprise the optical element near described array light sensor, described optical element with described little be assembled into be configured to as cell instrument basically confocal.
23. little picture cell instrument that is assembled into according to claim 22, wherein, described optical element comprises the array of micropore.
24. little picture cell instrument that is assembled into according to claim 22, wherein, described optical element comprises fibre bundle.
25. little picture cell instrument that is assembled into according to claim 1, wherein, described collector lens gathering also focuses on the light that sends by fluorescence from described cell again.
26. a method of carrying out cytometry, described method comprises:
Produce light beam with light source;
To be focused to from the light of described light beam at a plurality of focusing points of irradiation of experience with the sense position place of the relative motion of cell;
To assemble from the light that described cell sends also focuses on the array light sensor again;
Produce expression from described array light sensor and drop on light intensity on the described array light sensor and the signal of distribution; And
Come to make up based on the signal from described array light sensor at least in part the digital picture of described cell with processing unit.
27. method according to claim 26 also comprises: described signal is converted to the numerical value that expression drops on the pattern of the light on the described array light sensor.
28. method according to claim 26, wherein, the digital picture that makes up described cell also comprises:
Obtain a series of sequential readings of the light that drops on the described array light sensor;
Follow the tracks of individually photoreading from described array light sensor corresponding to each described focusing point of irradiation; And
Come independent described photoreading is carried out spatial calibration based on the gait of march of known system geometries, described cell and the frequency that obtains described photoreading at least in part.
29. method according to claim 26 also comprises: the light that sends from described cell is carried out filtering, optionally to stop by the light of the wavelength of described light source emission and the light of the wavelength that sends by fluorescence from described cell is passed through.
30. method according to claim 26 also comprises: the optical element near described array light sensor is set, described optical element with described little be assembled into be configured to as cell instrument basically confocal.
31. little picture cell instrument that is assembled into comprises:
Sense position, the relative motion of experience and cell;
Light source;
Concentrating element, described concentrating element will be focused to from the light of described light source many focusing illuminated line at described sense position place, so that described cell is shone by one or more described focusing illuminated line when passing described sense position;
Optical sensor; And
Collector lens will assemble also from the light that described cell sends again focusing on the array light sensor.
32. little picture cell instrument that is assembled into according to claim 31, wherein, described optical sensor comprises the array of pixel.
33. little picture cell instrument that is assembled into comprises:
Sense position, the relative motion of experience and cell;
Light source;
Concentrating element, described concentrating element will be focused to from the light of described light source a plurality of focusing points of irradiation or the line at described sense position place, so that described cell is shone by one or more described focusing points of irradiation or line when passing described sense position;
Array light sensor;
Collector lens will assemble also from the light that described cell sends again focusing on the described array light sensor;
Processing unit is analyzed signal from described optical sensor so that cell is sorted out; And
Sorting mechanism is with one of at least two collection channels of the cell sorted out guiding.
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Also Published As
Publication number | Publication date |
---|---|
EP2548000A4 (en) | 2014-08-13 |
US9068916B2 (en) | 2015-06-30 |
EP2548000A1 (en) | 2013-01-23 |
JP2013522629A (en) | 2013-06-13 |
CA2792628A1 (en) | 2011-09-22 |
US20110222051A1 (en) | 2011-09-15 |
WO2011116003A1 (en) | 2011-09-22 |
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